KR100566020B1 - Planar Polarizer For LCD Projectors - Google Patents

Abstract

The present invention relates to a liquid crystal display projector comprising a light source, a collimating lens, a planar polarization converter, a liquid crystal display panel and a projection lens. The aiming lens is optically aligned to receive the light beam from the light source and produce a collimated light beam. The planar polarization transducer is optically aligned in front of the aiming lens to accommodate the aimed light beam. The polarization converter includes a prism film having a first prism surface, a reflective polarizing film, and a quarter-wave retarder film positioned between the prism film and the polarizing film sheet. The prism surface has an alternating transmissive prism facet and a reflective prism facet positioned at a complementary bottom angle, wherein the reflective prism facet is positioned at a second base angle β and the transmissive prism facet is generally positioned at a first base angle equal to 180 ° -β do.

Liquid crystal display projector, polarization converter

Description

Planar Polarizer For LCD Projectors}

The present invention relates to a liquid crystal display (LCD) projection system comprising a flat polarization transducer and a novel flat polarization transducer. More specifically, the present invention relates to a small planar polarization converter for use in, for example, a full-color large-diagonal LCD projection system. Large diagonal LCD devices are defined as devices with diagonal surface dimensions over 150 mm. Polarization transducers of the present invention include planar components that efficiently produce linearly polarized light over a large area from an unpolarized light source.

Some single panel LCD devices, specifically projection systems, require polarization. An efficient planar polarizer can greatly assist in the design of small and portable LCD devices.

Unpolarized light includes a linear component and a right angle component. A common method of producing polarization for LCD projection panels involves the use of polarizing beam splitter (PBS) cubes. The linearly polarized component light is transmitted by the PBS cube and sent to the LCD panel, while the perpendicular component is reflected in the vertical direction. Another common method of generating polarization involves the use of an absorbing dye or an iodine based polarizer film positioned between the light source and the LCD panel. The absorbing film transmits single component linearly polarized light in one direction, while the right angle component absorbs. Absorbing polarizer films are often integrally incorporated into commercially available LCD panels. Alternatively, a separate polarizer plate can be located between the light source and the LCD.

Both the PBS cube and absorbing polarizer methods are inefficient in that only up to half of the light available from the light source is converted to transmissive polarization through the LCD panel. Attempts have been made to recycle polarization components reflected from the PBS cube. However, solid glass PBS cubes are bulky and cannot be applied for small or flat applications.

Recently, reflective polarizing sheet films have been developed. Instead of an absorbing sheet polarizer, the use of a reflective polarizing sheet film makes it possible to reflect back the s-polarized component of the light beam in the direction of the light source. Methods of returning the reflected polarization back to the spherical reflector behind the light source and back to the LCD panel have been described. However, these methods require extremely accurate positioning of the optical components for efficient recycling of light. In addition, these methods are also not readily suitable for small use.

Other systems have attempted to improve efficiency by recycling the polarized light reflected from various types of polarization generating films without returning light to the light source. Some of these systems use polarization conversion devices that use holographic optics to separate polarization components. All of these systems can occupy a significant amount of space, making them unsuitable for large-gate LCD panels or small sizes.

Recently, systems have been published that convert polarization and recycle polarization in plate-like devices.

1 illustrates an initial plate like transducer 10 illustrated in US Pat. No. 5,566,367. The beam of collimated incident light that is not polarized is reduced to a collimated subbeam 22 by the lance-like element 30 comprising a converging microlens 32 and a concave microlens 34. The subbeam 22 is incident on the second prism element 40. Linearly polarized beam 24 exits prism element 40. Prism element 40 includes a first incident side prism 42 having a series of quarter-wave retarder film 44 and a reflective polarizing beam splitting coating 46. The entire reflector 48 is formed on the contact surface of the side prism 50. In such polarization transducer 10, accurate positioning between the converging microlenses 32 and the concave microlenses 34 is required. More importantly, accurate positioning between the lenticular element 30 and the second prism element 40, more precisely between the concave microlens 34 and the first incident prism 42, is essential for efficient operation. to be. Likewise, precise thickness control of the devices is similarly required. Their exact positioning and thickness requirements present significant manufacturing difficulties with the attachment of the coating needed on the selective prism surface.

Summary of the Invention

The present invention includes a thin planar device that efficiently converts unpolarized light into linearly polarized light suitable for use in an LCD projector. This system allows the use of linear microprism sheet elements, with separate wide-angle reflecting polarizers and retarder sheet films. No selective optical coating is needed on any microprism device, and the action of the planar polarization transducer is independent of device positioning and thickness.

The planar polarization transducer for polarization of light beams according to the invention is in turn an optically aligned light deviation assembly, a double-sided prism film, a quarter wavelength retarder film, a planar reflective polarizer film, an optional absorbing polarizing film and a beam. It includes an integrated film.

The light biasing assembly is directed toward the double-sided prism film at an angle β. The prism film has a first prism surface and a second prism surface, and the first prism surface has an alternating transmissive prism facet or surface and a reflective prism facet or surface positioned at a complementary base angle. The reflective prism face is positioned at the second base angle β ₂ , while the transmissive prism face is positioned at the inner first base angle β ₁ and generally at a total base angle such as 180 ° -β ₂ , where β1 = β2 = β. do. A plurality of retroreflective linear microprisms with a vertex angle α (where α ₂ + 2β ₂ = 180 °) are located on the surface of the reflective prism facet. Both the absorbing polarizing film and the reflecting polarizing film are aligned along the same polarization axis. In a preferred embodiment, the retarder film, the reflective polarizer film and the absorbing polarizer film are stacked and mounted on a thin glass substrate.

In an alternative embodiment, the light biasing assembly comprises at least one comfort prism sheet or at least one comfort prism sheet and a collimator. In a preferred embodiment β is generally equal to 45 °.

The liquid crystal display projector according to the present invention includes a light source for generating a light beam, an aiming lens optically aligned to receive a light beam and produce a collimated light beam, and optically aligned to receive the aimed light beam. Same planar polarization transducer. The liquid crystal display panel is optically aligned with the polarization transducer, and the projection lens assembly is optically aligned with the liquid crystal panel.

1 is a cross-sectional view of a plate-like polarization transducer of the prior art.

2 is a cross-sectional view of a planar polarizer according to the present invention.

3 is an enlarged detailed cross-sectional view of the planar polarization converter illustrated in FIG. 1.

4 is a cross-sectional view of an alternative embodiment of the assembly of the broad piece according to the invention.

5 is a cross-sectional view of a second alternative embodiment of the assembly of the wide piece according to the invention.

6 is a perspective view of a planar polarization transducer according to the present invention with an oblique polarization transmission axis.

7 is a simplified schematic side view of an LCD projection system according to the present invention.

8 is a simplified schematic plan view of a second LCD projection system according to the present invention.

9 is a simplified schematic plan view of a third LCD projection system according to the present invention.

10 is a simplified schematic plan view of a fourth LCD projection system according to the present invention.

11 is a simplified schematic plan view of a fifth LCD projection system according to the present invention.

2 illustrates a cross-sectional view of a planar polarization converter 100 according to the present invention for polarizing the beam 12 of aimed incident light without polarization. The planar polarization transducer 100 is an optically aligned assembly 13, a double-sided prism film or sheet 140, a quarter wavelength retarder film or sheet 160, a planar reflective polarizer film or sheet, all of which are optically aligned in turn. 170), optional absorbing polarizing film or sheet 180 and beam integrating film or sheet 190. The term "optically aligned" is defined as the alignment of the light beam along the light path, including when the light path is bent by a reflective surface or deviated by a prism surface, for example. The order of incidence of the light beams along the light path determines the front and rear positions for the optical element of the present invention.

The optical positioning device 130 includes an aiming element and an optical biasing element. In this embodiment, the light aiming and comfort assembly 130 includes a collimating lens 102 (illustrated in FIG. 7) and a first prism sheet 132 that convert the converging beam 110 into the aimed beam 120. do. The first prism sheet 132 includes a planar surface 134 and a series of biasing prisms 136.

The light beam 120 is incident on the first prism sheet 132 at the incident angle θ. The biasing prism 136 diverts the aimed light to the base angle β (base angle measured counterclockwise relative to the reference base 112) by total internal reflection (TIR) and refraction. In this embodiment, β = 45 ° and θ = 90 °. The biasing prism 136 has a base angle α ₁ (shown better in FIG. 3) and a deviation angle δ measured for the angle of incidence, where θ = β + δ. Therefore, δ = 45 °. For the biasing prism 136 of the embodiment illustrated in FIG. 2, the base angle α ₁ = 59.15 ° for acrylic plastics having a refractive index n = 1.492 for yellow light. The width of the prism grooves is typically 0.1 mm to 0.5 mm, and the representative sheet thickness is 1 mm to 3 mm.

The off light rays 122 then enter the double-sided prism sheet 140. Double-sided prism sheet 140 includes a lower prism surface 142 and an upper prism surface 152. The prism surfaces 142 and 152 have a plurality of prisms, each prism being oriented to the first and second side base angles that are complementary, i.e., 180 degrees by adding the first and first side base angle values. Or has a surface. The lower prism surface has an alternating transmissive prism first side 144 and a reflective prism second side 146 sandwiched therebetween. The reflective prism second side surface 146 is positioned at the second side bottom angle β ₂ . The transmission prism first side 144 is located at the inner side bottom angle β ₁ (measured clockwise relative to the reference plane), and the first side bottom angle is generally equal to 180 ° -β ₁ . Upper prism surface 152 includes alternating first and second transmissive prism facets 154 and 156 sandwiched or interposed between _first and second facet foot angles 180-β ₁ and β ₂ furnaces, respectively.

In the planar polarization converter 100, | β1 | = │β2 | = │β│ = 45 degrees, and is independent of the refractive index of the material. A value of β = 45 ° provides manufacturing efficiency by avoiding locking angles that make the duplicated parts difficult to separate. The first side surfaces 146 and 156 are parallel to each other and are positioned perpendicular to the parallel second side surfaces 144 and 154. However, one of ordinary skill in the art will recognize that a number of different values may be selected for each of the foregoing.

Since the transmissive prism facets 144 and 154 are parallel to each other and perpendicular to the path of the rays 122 that deviate, the rays 122 pass through the double-sided prism sheet 140 without deviating. Light ray 122 is then made of a ¼ wavelength retarder 160 such as, for example, an optical band type ¼ wavelength retarder, such as Nitto Denko type NRF-QF03A manufactured by Nitto Denko Corporation of Tokyo, Japan. Passing through the planar sheet, it impinges on a planar sheet of a wide angle polarization splitting film 170, for example 3M Dual Brightness Enhancement Film (DBEF), a 3M product of St. Paul, Minn. . The p-polarized component 124a of the light ray 122 is transmitted by the polarizer film 170, while the s-polarized perpendicular component 126 is angled 180 degrees-beta through the quarter wave retarder sheet 160. Reflected again. The quarter-wave retarder converts the s-component 126 into circularly polarized light rays 128a. Circularly polarized line 128a then passes through second prism face 156 of upper prism surface 152. Because the second transmissive prism face 156 is perpendicular to the light ray 128a, the light ray 128a passes through the upper prism surface 152 undistributed and onto the reflective face 146 of the lower prism surface 142. Crashes.

3 illustrates a detailed enlarged view of the planar polarization transducer 100, including one of the reflective side surfaces 146. Reflective face 146 includes a series of microprisms 148 formed on the surface of the prism face. Microprism 148 has a vertex angle α ₂ = 90 ° and acts as a TIR retroreflector, with α ₂ + 2β = 180 °. Light ray 128a is reflected back to light ray 128b at the surface of reflective surface 146. Reflected line 128b returns at the same angle and in the opposite direction as incoming line 128a. In the illustrated embodiment, the base prism of the lower prism surface 142 has a width between 0.1 mm and 0.5 mm, while the retroreflective microprism 148 has a width between 0.01 and 0.05 mm.

As illustrated in FIG. 2, the reflected circularly polarized light 128b is then converted to p-polarized light 124b as it passes through the quarter-wave retarder film 160. The p-polarized light 124b is transmitted by the reflective polarizer film 170, and then the p-polarized light 124b is impinged on the prism beam integrating sheet 190. Iodine or dye cleanup absorbing polarizer film 180 may be placed in front of beam integrating sheet 190 to absorb any scattering components. Absorbing polarizing film 180 and reflective polarizing film 170 are both aligned along the same polarization axis. In an exemplary embodiment of the invention, the absorbing polarizer is a high contrast type iodine polarizer, for example Nitto Denko type EG1425DUHCARP, manufactured by Nito Denko Corporation, Tokyo, Japan.

Prism beam integrating sheet 190 includes a prism surface 194 and a lower planar surface 192 having a prism base angle γ. By refraction at the planar surface 192 and the prism surface 194, both the original p-polarized light 124a and the converted p-polarized light 124b are aimed. In an exemplary embodiment, the prism base angle γ = 66.1 ° for acrylic plastics having a refractive index n = 1.492 for yellow light. The width of the prism grooves on the prism surface is typically 0.1 mm to 0.5 mm, and the representative prism beam integrated sheet thickness is 1 mm to 3 mm.

The retarder film 160, the reflective polarizer film 170 and the absorbing polarizing film 180 are optically aligned, stacked and mounted on a thin glass substrate about 1 mm thick. When all the components are closely stacked, the total thickness of the resulting polarization transducer 100 is 8 mm to 10 mm. When an extended and aimed unpolarized light beam is incident on this planar polarization transducer 110, a collimated polarized beam is produced.

4 illustrates an alternative embodiment of the light biasing element 232 of the light biasing assembly according to the present invention. The light biasing element 232 includes a first prism element 240 and a second prism element 260. The first prism element 240 includes an upper prism surface 244 having a lower planar surface 242 and a series of prisms 246. Each prism 246 has a first side 248 and a second side 250. In the present exemplary embodiment, the bottom planar surface 242 is vertical and the second side surface 250 is parallel to the incoming collimated unpolarized light beam 220. The first subsurface 248 has a base angle φ ₁ equal to or greater than the angle of the TIR with respect to the light ray 220. The incoming ray of light 220 passes through the lower planar surface 242 without deviating and is deviated by the TIR at the first side 248 of the prism 246 of the upper prism surface 244, and then the second side 250 ) Is refracted as the inner light ray 222 at the base angle = φ ₁ .

The second prism element 260 includes a lower prism surface 262 and an upper planar surface 264. The lower prism surface includes a plurality of prisms 266, each prism having a first side 268 and a second side 270. The second side surface 27 is oriented at right angles to the inner light ray 222. The first side surface 268 is oriented at the base angle of φ ₁ . The light rays are refracted at the planar surface 264 without deviating from the plane 270, creating a deviation angle δ for the emission line, where δ + β = 90 °. In this example, β = 45 ° and the deviation angle δ = 45 °. Although the prism element of the polarization converter described is designed with a deviation angle δ = 45 °, those skilled in the art can manufacture a polarization conversion system using the teachings of the present invention by varying this deviation angle.

Since the incoming line 220 is parallel to the prism face surface 250 and the inner line 222 is parallel to the prism face surfaces 248 and 268, there is no geometric blocking loss of the light beam and there is minimal geometric processing loss. .

φ₁이다.5 illustrates a second alternative light biasing element 332 of the light biasing assembly according to the present invention. In this embodiment, the preferred deviation β for the emission light beam 32 is equal to 45 °. The light biasing element 332 includes a first prism element 340 and a second prism element 360. The first prism element 340 includes an upper prism surface 344 having a lower planar surface 342 and a series of prisms 346. Each prism 346 has a first side 348 and a second side 350. In the light biasing element 332, the lower planar surface 342 is perpendicular and parallel to the aimed unpolarized light ray 320 that the second side surface 350 enters. The base angle φ ₁ of the first side surface 348 is smaller than the angle of the TIR with respect to the light ray 320. The incoming ray of light 320 passes through the lower planar surface 342 and is refracted by the inner angle φ ₂ as the inner ray 322 at the first side 348. In this embodiment, φ ₂

φ ₁ .

The second prism element 360 includes a lower prism surface 362 and an upper planar surface 364. Lower prism surface 362 includes a plurality of prisms 366, each prism 366 having a first side 368 and a second side 370. The second side surface 370 is oriented at right angles to the inner light ray 322. The first side 368 is oriented at the base angle of φ ₂ and parallel to the inner light ray 322. The inner light ray 322 does not deviate from the second side surface 37, but is refracted at the planar surface 364, creating a deviation angle δ with respect to the emitted line 324. delta + β = 90 °. In this example, β = 45 ° and the deviation angle δ = 45 °. The relationship between φ ₂ and δ is explained by Snell's Law:

/2-φ₂)sin (δ) = n sin (

/ 2-φ ₂ )

δ = asin (n cos (φ ₂ ))

Where n = refractive index of element 36.

The incoming aimed ray 320 is refracted at the planar surface 342, but is refracted by the first side surface 348 and the planar surface 364. The emission beam 324 is emitted at an angle of deviation = 45 degrees. Since the second side surface 350 is parallel to the incoming light ray 320 and parallel to the inner line 322, there is minimal geometric blocking loss of light through the elements.

The present invention includes the case where the polarization transmission axis of the receiving liquid crystal display (LCD) panel is inclined, that is, the transmission axis of the polarizing film is not horizontal or vertical. 6 illustrates a planar polarization transducer assembly 400 comprising a prism sheet according to the present invention having a tilted orientation of the polarization transmission axis 410. The prism sheet has a groove 420 positioned diagonally with respect to the polarization axis 410. Prism groove 420 is alternatively oriented parallel to polarization axis 410. Alternative embodiments may include grooves having a vertical or horizontal orientation or an angle orientation other than 45 °.

FIG. 7 illustrates a linear form of a single panel LCD projector assembly 500 that includes the planar polarization converter 100 illustrated in FIGS. 2 and 3. The LCD assembly 500 includes a planar polarization converter 100, a single panel LCD 540, including a rear spherical reflector 510, a light source 520, a condenser lens 530, a Fresnel collimating lens 102. , Fresnel field of view lens 550 and projection lens 560, all of which are generally optically aligned along a linear path.

The light source 520 is generally located behind the glass condenser lens 530 and near the radius of the curve of the rear spherical reflector 510. The term "light source" includes any radiation source that can be used with projection systems, including incandescent, tungsten, quartz-halogen, metal halides, and other arc discharge lamps, as well as other light sources known in the art. In the LCD assembly 500, the light source 520 is a metal halide type 400, such as Osram type HMP 400 DE, Osram GmbH, Munniger, Germany, located about 90 mm from the Fresnel collimating lens 102. Wattage discharge lamp.

Light source 520 produces unpolarized light 108 that is directed forward by spherical reflector 520 and refracted by condensing lens 530. In the present exemplary embodiment, the rear glass spherical reflector 510 has a curvature radius of 32 mm with a dichroic reflective coating, and the condenser lens 530 receives the light beam 108 from the lamp 520 and generates light A glass spherical condenser lens that directs the beam 110 to a 90 mm focal length Fresnel collimating lens 102.

Divergence light beam 110 is aimed at light beam 120 aimed by Fresnel lens 102. The planar polarization converter 100 converts the unpolarized collimated light beam 120 into a linearly polarized collimated light ray 124 which impinges on the single panel LCD 540. Light beam 124 passes through the LCD panel to form an image beam 508. Fresnel field of view lens 550 converges image beam 508 into projection lens 560. The projection lens 560 projects the image of the LCD panel 540 onto a display screen.

In an exemplary embodiment of the invention, the assembled planar polarization transducer 100 is about 140 mm wide x 110 mm high x 10 mm thick, 160 mm diagonal SVGA TFT-LCD panel 540, Sharp Ink, Japan Nara. . (Sharp, Inc.), for example, before Sharp model number LQ64SP1. The linear groove of the polarization converter is oriented perpendicular to the polarization transmission axis of the LCD panel 540. The Fresnel converging lens 550 converges light with a projection lens 550 having a 152 mm focal length and a 167 mm focal length, f / 5.6 three element projection lens that projects an image of the LCD panel.

8 shows an alternative agent with a light source 620, planar polarization transducer 604, Fresnel collimating lens 602, single panel LCD 640 and Fresnel converging lens 650, with the elements optically aligned. Illustrates a two LCD projector assembly 600. LCD projector assembly 600 may also include a projection lens 660 and a rear spherical reflector, and a condenser lens similar to that illustrated in FIG. In the projector arrangement of the LCD projector assembly 600, the light source 620 and Fresnel lens collimator 602 are positioned with a base 180 ° -β off axis. In this example, β = 45 ° and the base angle is equal to 135 °. The off-axis arrangement of the collimator 602 does not require an optical polarization element in the optical positioning assembly of the polarization transducer 604. In an alternative embodiment, the collimator may be located at an off-axis base angle of λ ₁ , and the light positioning assembly may include an optical deflector having a deviation angle of λ ₂ , where λ ₁ + λ ₂ = β . By adding a rotating half-wave retarder sheet 630 inserted between the polarization transducer 604 and the LCD panel 640, the polarization axis of the polarization converter is the polarization of the LCD panel when the LCD panel polarization axis is not horizontal or vertical. It can be rotated to align with the axis.

9-11, elements similar to LCD assembly 600 are indicated by the same reference numerals. 9 shows a full-color LCD projector assembly 700 having a large gate with a dense arrangement, where the path of the light generated by the light source 720 is folded by the plane mirror 770. The Fresnel collimating lens 702 is directed. LCD projector assembly 700 includes a planar polarizer 704 having a light positioning assembly that includes a Fresnel collimating lens 702. The Fresnel lens collimator 702 is positioned with a base 180 ° -β off axis, while the other polarization transducer is aligned parallel to the mirror and the LCD 740. Rotating half-wave retarder sheet 730 is also shown. In this example, β = 45 °. FIG. 10 shows another LCD projector assembly 800 with a compact arrangement, where the Fresnel lens collimator and the planar mirror are combined into an off-axis Fresnel reflective collimator 880 to bend the light path and to the light source 820. The light rays 808 generated by this are oriented and aimed at. The reflective collimator is positioned at a base angle of 180-beta and reflects and aims the ray 808 into the aimed light beam 810. LCD projector assembly 800 further includes polarization transducer 804, half-wave retarder sheet 830, and LCD panel 840, Fresnel converging lens 850, and projection lens 860. The positioning of the reflective collimator 880 also does not require a light biasing element relative to the polarization transducer 804.

11 illustrates another example embodiment of an LCD projector assembly 900. LCD projector assembly 900 has a light positioning assembly that includes a sheet of light 932 and a Fresnel lens collimator 902, separate from other elements and positioned at right angles to the planar transducer 904. The light source 920 is located behind the Fresnel lens collimator 902. The Fresnel lens collimator 902 aims the light and the sheet of light biasing 932 is aimed at the base angle β and directs the unpolarized light beam to the planar polarization converter 904.

The polarization conversion system of the present invention has several advantages over those described in the prior art. First, the action of the system is independent of the transverse positioning of the prism surface opposite the prism sheet or double-sided prism sheet. Second, the effect on the system is independent of the prism sheet thickness or the separation between the prism sheets. Third, no selective coating is required on any prism surface on these sheets. The suppression and polarization separation film can be applied as a flat sheet and separated from the prism sheet. These features greatly simplify the manufacture of polarization transducers and make the manufacturing costs more efficient. All prism sheets can be manufactured by standard plastic molding techniques. If desired, the prism sheets may also include an antireflective coating to increase light transmission. Finally, a number of small and adaptable LCD projector assembly arrangements are possible, and thus the invention can be used in a variety of applications.

The embodiments described and illustrated herein are illustrative only and should not be considered as limiting the scope of the invention. Those skilled in the art will recognize that other variations and modifications may be made depending on the nature and scope of the present invention.

Claims (26)

The reflective prism facet located at the second base angle β and the alternating transmissive prism facet 144 and the reflective prism facet 146 positioned at the complementary bottom angle of the transmissive prism facet generally positioned at the first base angle equal to 180 ° -β. Prism film 140 having a first prism surface 142 having, ¼ wavelength retarder film 160, and Reflective polarizing film 170, positioning a quarter-wave retarder film between the prism film and the polarizing film sheet And a plane polarization transducer (100) for polarizing the light beam, the order of incidence along the light path of the light beam determining a front and rear position. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete Assembly 130 of an optical piece for exiting the light beam at an angle β, The first prism surface has an alternating transmissive prism facet 144 and a reflective prism facet 146 with a complementary angle, wherein the reflective prism facet is generally positioned at a second base angle equal to β and the transmissive prism facet is generally 180 Located at the same base angle as FIG.-Beta, the surface of the reflective prism face has a plurality of retroreflective microprisms 148, and the second prism surface has alternating first and second transmissive prism facets 154, 156. Wherein the first prism surface 142 and the first transmissive surface are generally parallel to the transmissive prism face of the first prism surface and the second transmissive face is generally parallel to the reflective prism face of the first prism surface. Double-sided prism film 144 having two prism surfaces 152, ¼ wavelength retarder film 160, The planar reflective polarizing film sheet 170 for positioning the ¼ wavelength retarder film between the prism film and the reflective polarizing film sheet, A reflective polarizing film that is all aligned along the same polarization axis and an absorbing polarizing film 180 located behind it, and Beam Integrating Film (190) Located Behind the Absorbing Polarizing Film And a plane polarization transducer (100) for polarizing the light beam, the order of incidence along the light path of the light beam determining a front and rear position. A light source 520 for generating a light beam, Optically aligned aiming lens 102 which receives the light beam and produces a collimated light beam, A first prism surface having an alternating transmissive prism facet and a reflective prism facet positioned at a complementary base angle, a reflective prism facet positioned at a second base angle β and a transmissive prism facet positioned generally at a first base angle equal to 180 ° -β. Having prism film, ¼ wavelength retarder film 160, and Reflective Polarizing Film (170) Wherein the quarter wave retarder film is optically aligned to receive the aimed light beam and produce a polarized light beam, positioned between the prism film and the reflective polarizing film sheet, A liquid crystal display panel 540 optically aligned with a polarization transducer that receives polarized light beams to produce an image beam, and Projection lens assembly 560 optically aligned with a liquid crystal panel receiving the image beam Liquid crystal display projector 500 comprising a. delete delete delete delete delete delete delete

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